Integrated Luminosity with 100 ppm Precision, Methods for s Precision of 1 ppm, and Beyond Standard Model Sensitivity using Photonic Events, at e+e- Higgs Factories

Abstract

Future electron-positron () colliders, operating as Higgs factories or Z factories, promise unprecedented precision electroweak measurements that are vital to testing the Standard Model (SM) and exploring physics beyond it. Here we present work on the precision of integrated luminosity (L) and center-of-mass energy (s), measurements that are needed to make future precision measurements possible. We also conduct these studies for the International Linear Collider (ILC) from the Z pole (mZ) to 1~TeV to provide a comprehensive study of these issues for future colliders. Paths to 100 parts-per-million (ppm) precision on L are presented, with focus on small-angle Bhabha scattering (SABS) and two-photon production (diphotons, γγ). Previous studies found that beam deflection of SABS events introduce biases on L of 10-2. To address this, we present a novel method that uses Mller scattering with SABS to measure beam deflection and minimize its effect on L. We present a proposal for a Highly Granular Luminosity Calorimeter, the GLIP LumiCal, and its design considerations. We demonstrate that the GLIP LumiCal can achieve ≈35 ppm precision on L precision with diphotons for all values of s and that the current LumiCal design is insufficient for reaching 1000 ppm. Multiple methods for precision s estimation are presented. We introduce the use of Kernel Density Estimation (KDE) to ensure that s is measured accurately and precisely The utility of photon measurements is extended to photon with invisible (X0γ) events where we demonstrate methods to measure left-handed and right-handed neutrino couplings and put constraints on Beyond Standard Model (BSM) physics.

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